Inverting difference oscillator

ABSTRACT

The described embodiments provide a configurable pulse generator circuit. More specifically, the described embodiments include a pulse generator circuit; an inverting difference oscillator (IDO) enabling circuit coupled to the pulse generator circuit; and a disable signal coupled to the IDO enabling circuit. When the disable signal is asserted, the IDO enabling circuit is disabled and the pulse generator circuit is configured as a pulse generator. In contrast, when the disable signal is deasserted, the IDO enabling circuit is enabled and the pulse generator circuit is configured as part of an IDO.

RELATED APPLICATIONS

This application is a divisional application of, and hereby claimspriority under 35 U.S.C. §120 to, pending U.S. patent application Ser.No. 12/495,088, entitled “Inverting Difference Oscillator,” filed 30Jun. 2009, by Anand Dixit and Robert P. Masleid.

This application is related to U.S. patent application Ser. No.12/494,663, entitled “Configurable Pulse Generator,” filing date 30 Jun.2009, by Robert P. Masleid and Anand Dixit. This application is alsorelated to U.S. patent application Ser. No. 12/425,176, entitled“Economy Precision Pulse Generator,” filing date 16 Apr. 2009, byinventors Robert P. Masleid, David J. Greenhill, and Bijoy Kalloor.

BACKGROUND

1. Field of the Invention

The described embodiments relate to measurement circuits. Morespecifically, the described embodiments relate to an invertingdifference oscillator.

2. Related Art

In modern integrated circuits, circuit designers need to know theprecise delay of circuit elements (i.e., logic gates, functional blocks,etc.) in order to effectively optimize a circuit design. Consequently,many techniques have been developed for determining the delay of circuitelements. One such technique involves using a difference oscillator todetermine the delay of non-inverting circuit elements.

For example, FIG. 1 presents an exemplary difference oscillator 100 thatcan be used to measure the delay of a non-inverting circuit element(device under test (DUT) 102). As shown in FIG. 1, difference oscillator100 includes a multiplexer (MUX) 104 and an inverter chain 106 in aconfigurable circuit path loop. By using MUX 104, difference oscillator100 can be configured so that the circuit path loop follows eitherreference path 108, which excludes DUT 102, or test path 110, whichincludes DUT 102. Because device 102 is non-inverting and there are anodd number of inversions in inverter chain 106, difference oscillator100 functions as a ring oscillator regardless of whether the circuitpath follows test path 110 or reference path 108.

When measuring the delay of DUT 102, difference oscillator 100 can beoperated first in a configuration that uses reference path 108, and thenin a configuration that uses test path 110 to determine the oscillatingfrequency in each configuration. The oscillating frequencies can then beused to determine the difference in the period of the differenceoscillator for the two configurations. Next, the delay of DUT 102 can becomputed by dividing the determined difference in half.

To determine the delay across the non-inverting DUT 102, differenceoscillator 100 must function as a ring oscillator regardless of theconfiguration of the circuit path loop. More specifically, differenceoscillator 100 must function as a ring oscillator both when configuredto use reference path 108, where DUT 102 is excluded, and whenconfigured to use test path 110, where DUT 102 is included.Consequently, difference oscillator 100 is limited to applications wherea delay is to be determined for a non-inverting DUT 102.

SUMMARY

The described embodiments provide a configurable pulse generator circuit(e.g., pulse generator 202). More specifically, the describedembodiments include: the pulse generator circuit; an invertingdifference oscillator (IDO) enabling circuit coupled to the pulsegenerator circuit; and a disable signal coupled to the IDO enablingcircuit. When the disable signal is asserted, the IDO enabling circuitis disabled and the pulse generator circuit is configured as a pulsegenerator. In contrast, when the disable signal is deasserted, the IDOenabling circuit is enabled and the pulse generator circuit isconfigured as part of an IDO.

Some embodiments include a selection circuit. In these embodiments, oneinput of the selection circuit is coupled to an output of a previouspulse generator circuit, and another input of the selection circuit iscoupled to an output of the pulse generator circuit. A control input ofthe selection circuit is coupled to the disable signal. When the disablesignal is deasserted, the selection circuit is configured to forward theoutput from the previous pulse generator circuit to the pulse generatorcircuit. In contrast, when the disable signal is asserted, the selectioncircuit is configured to forward the output of the pulse generatorcircuit as a feedback to the pulse generator circuit.

Some embodiments include an n-type metal-oxide-semiconductorfield-effect (NMOS) transistor in the pulse generator circuit coupledbetween an internal node in the pulse generator circuit and VSS. A gateconnection for the NMOS transistor is coupled to an output from theselection circuit. In addition, these embodiments include two p-typemetal-oxide-semiconductor field-effect (PMOS) transistors in the IDOenabling circuit coupled in series between the internal node in thepulse generator circuit and VDD. A gate connection for the first of thePMOS transistors is coupled to the disable signal, and a gate connectionfor the second of the PMOS transistors is coupled to the output of theselection circuit.

Some embodiments include a second selection circuit. In theseembodiments, one input of the second selection circuit is coupled to theoutput of the previous pulse generator circuit, and another input of theselection circuit is coupled to the output of the pulse generatorcircuit. A control input of the selection circuit is coupled to a bypasssignal. When the bypass signal is asserted, the second selection circuitis configured to forward the output of the previous pulse generatorcircuit to a subsequent pulse generator circuit without the signalpropagating through a set of inverting circuit elements in the pulsegenerator circuit. In contrast, when the bypass signal is deasserted,the second selection circuit is configured to forward the output of thepulse generator circuit to the subsequent pulse generator circuit.

In some embodiments, a clock signal is coupled to the pulse generatorcircuit. When operating as a pulse generator, the pulse generatorcircuit is configured to output pulses in response to each rising edgeof the clock signal.

Some embodiments include a disable signal coupled to the pulse generatorcircuit. The pulse generator circuit is configured so that the pulsegenerator circuit is disabled when the disable signal is asserted.

The described embodiments provide an inverting difference oscillatorcircuit. The inverting difference oscillator circuit includes N stages,each stage including: (1) a circuit element path that includes at leastone inverting circuit element; (2) a bypass path; and (3) a selectioncircuit. One input of the selection circuit is coupled to the circuitelement path, and another input of the selection circuit is coupled tothe bypass path. An output of the selection circuit is coupled to thebypass path and to the circuit element path in a next stage.Additionally, an output of a selection circuit in a last stage iscoupled to the bypass path and to the circuit element path in a firststage to form a circuit path loop.

The inverting difference oscillator also includes N control signals,wherein each control signal is coupled to a separate selection circuit.The control signals can be used to configure the inverting differenceoscillator as a ring oscillator by forwarding the output from thecircuit element path in selected stages, and forwarding the bypass pathin any other stages, to configure the circuit path loop as a ringoscillator that includes an odd number of inverting circuit elements.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 presents a difference oscillator.

FIG. 2 presents a block diagram of a system in accordance with thedescribed embodiments.

FIG. 3A presents an inverting difference oscillator in accordance withthe described embodiments.

FIGS. 3B-3E present exemplary circuit path loop configurations in aninverting difference oscillator in accordance with the describedembodiments.

FIG. 4 presents a flowchart illustrating a process for computing a delayof a device under test using an inverting difference oscillator inaccordance with the described embodiments.

FIG. 5A presents a schematic view of a pulse generator in accordancewith the described embodiments.

FIGS. 5B-5D provide schematic views of circuit paths in a pulsegenerator in accordance with the described embodiments.

FIG. 6 presents a flowchart illustrating a process for configuring apulse generator coupled to one or more other pulse generators as aninverting difference oscillator in accordance with the describedembodiments.

In the figures, like reference numerals refer to the same figureelements.

DETAILED DESCRIPTION

The following description is presented to enable any person skilled inthe art to make and use the described embodiments, and is provided inthe context of a particular application and its requirements. Variousmodifications to the described embodiments will be readily apparent tothose skilled in the art, and the general principles defined herein maybe applied to other embodiments and applications without departing fromthe spirit and scope of the described embodiments. Thus, the describedembodiments are not limited to the embodiments shown, but are to beaccorded the widest scope consistent with the principles and featuresdisclosed herein.

The data structures and code described in this detailed description aretypically stored on a computer-readable storage medium, which may be anydevice or medium that can store code and/or data for use by a computersystem. The computer-readable storage medium includes, but is notlimited to, volatile memory, non-volatile memory, magnetic and opticalstorage devices such as disk drives, magnetic tape, CDs (compact discs),DVDs (digital versatile discs or digital video discs), or other mediacapable of storing code and/or data now known or later developed.

The methods and processes described in the detailed description sectioncan be embodied as code and/or data, which can be stored in acomputer-readable storage medium as described above. When a computersystem reads and executes the code and/or data stored on thecomputer-readable storage medium, the computer system performs themethods and processes embodied as data structures and code and storedwithin the computer-readable storage medium.

Furthermore, the methods and processes described below can be includedin hardware modules. For example, the hardware modules can include, butare not limited to, application-specific integrated circuit (ASIC)chips, field-programmable gate arrays (FPGAs), and otherprogrammable-logic devices now known or later developed. When thehardware modules are activated, the hardware modules perform the methodsand processes included within the hardware modules.

Terminology

In the following description, we refer to signals being “asserted” or“deasserted.” When a signal is asserted, the signal is set to a logical“1” value. In some embodiments, the logical 1 is equivalent to thevoltage VDD in the system. For example, the logical 1 is a voltage of1.2 V in a system where VDD is 1.2 V. When a signal is deasserted, thesignal is set to a logical “0” value, which is typically VSS or 0 V.Note that although we describe embodiments where signals are assertedand deasserted using the indicated voltages, alternative embodiments canuse different voltages.

System

FIG. 2 presents a block diagram of a system 200 in accordance with thedescribed embodiments. System 200 includes a number of pulse generators201-203, a receiving circuit 204, and an (optional) monitoring device206. Pulse generators 201-203 are coupled in series to enableconfiguring pulse generators 201-203 as part of an inverting differenceoscillator (IDO).

Pulse generators 201-203 are circuits that can be configured to generatepulses. Pulse generators 201-203 can also be configured as part of anIDO (i.e., as a stage in an IDO “chain”), or can be disabled, whichcauses each pulse generator to output a steady signal on its outputnode. More specifically, pulse generators 201-203 include circuitstructures that can be used to configure each pulse generator as a pulsegenerator, as part of the IDO, or to disable the pulse generator,depending on the state of enable inputs for the pulse generator (e.g.,functional/IDO mode control 212 and pulse generator disable 210). Theconfiguration of pulse generators 201-203 is described in more detailbelow.

Note that in the following description we may describe the functions ofpulse generator 202 alone for clarity. However, pulse generators 201 and203 can include similar inputs and circuit structures and can functionin the same way as pulse generator 202. In addition, like pulsegenerator 202, pulse generators 201 and 203 can be coupled to receivingcircuits (not shown). Moreover, as shown by the ellipsis in FIG. 2, insome embodiments, one or more additional pulse generators are coupled inseries with pulse generators 201-203.

Receiving circuit 204 is a circuit that takes as an input the signaloutput by pulse generator 202. Generally, receiving circuit 204 can beany type of circuit that uses the pulse generated by pulse generator 202as a timing signal, a control signal, a reference signal, a data signal,or for another purpose. For example, receiving circuit 204 can be, butis not limited to, one or more individual circuit elements (e.g., pulselatches, domino circuits, memory elements, control circuits, etc.), asynchronous random-access memory (SRAM) or dynamic random-access memory(DRAM), a microprocessor, a controller, an application-specificintegrated circuit (ASIC).

As shown in FIG. 2, pulse generator 202 takes clock 208, pulse generatordisable 210, functional/IDO mode control 212, and bypass control 214 asinputs. Clock 208 is used as a triggering signal for pulse generator202. More specifically, a rising transition in clock 208 causes pulsegenerator 202 to generate a rising pulse on pg_out 216. In someembodiments, the signal on clock 208 has a periodic waveform.

Pulse generator disable 210 is a control signal that can be used toprevent pulse generator 202 from outputting any varying signal (e.g., apulsed signal or an oscillating signal) on pg_out 216. When asserted,pulse generator disable 210 causes pulse generator 202 to output asteady signal equivalent to VDD (i.e., logical “1”).

Functional/IDO mode control 212 is a control signal that can be used toconfigure pulse generator 202 as part of an IDO or as a pulse generator(i.e., in a “pulse generation mode”). When functional/IDO mode control212 is asserted (e.g., is a logical “1”), pulse generator 202 isconfigured as a pulse generator. In contrast, when functional/IDO modecontrol 212 is deasserted (e.g., is a logical “0”), pulse generator 202is configured as part of the IDO. When configured as part of the IDO,pulse generator 202 uses the output signal of the previous stage (e.g.,pulse generator 201), which is itself oscillating, as an input. Inaddition, instead of outputting a pulse on pg_out 216, pulse generator202 outputs an oscillating (periodic) waveform on pg_out 216. Asdescribed below, the periodic waveform output can be forwarded to thenext stage in the IDO (e.g., pulse generator 203).

In some embodiments, functional/IDO mode control 212 is a global signalthat is coupled to each pulse generator (i.e., pulse generators201-203). As described above, in these embodiments, deassertingfunctional/IDO mode control 212 configures a selection circuit in eachpulse generator to select the output from a previous pulse generator asa feedback for the pulse generator (instead of a local feedback path forthe pulse generator). In addition, deasserting functional/IDO modecontrol 212 configures each pulse generator to pass the received signalthrough a set of inversions within the pulse generator. Hence,functional/IDO mode control 212 enables pulse generators 201-203 to beconfigured as part of a ring oscillator that can be used as part of theIDO.

Bypass control 214 is a control signal that can be used to bypass pulsegenerator 202 in the IDO configuration. Generally, when bypass control214 is asserted for a given pulse generator stage (e.g., pulse generator202), a selection circuit in the pulse generator is configured to passan output signal from a previous pulse generator in the chain (e.g.,pulse generator 201) directly to a next pulse generator in the chain(e.g., pulse generator 203) without passing the output signal throughthe set of inversions in the pulse generator. In these embodiments,bypass control 214 enables system 200 to control the number of stages inthe ring oscillator of the IDO.

Monitoring device 206 is a device that takes the signal output by thechain of pulse generators as an input. In some embodiments, monitoringdevice 206 measures the signal output by the chain of pulse generatorsand uses the measured signal to help determine a delay of a selectedpulse generator in the chain of pulse generators. Determining the delayof a selected pulse generator in the chain of pulse generators isdescribed in more detail below.

Monitoring device 206 can be coupled to a display device, acomputer-readable storage medium, or another device. Upon determiningthe delay of a given pulse generator, monitoring device 206 can thendisplay the delay on the display device or write the delay to thecomputer-readable storage medium. Alternatively, in embodiments wheresystem 200 is a computer system, monitoring device 206 could forward thedetermined delay to an application or process within system 200 forhandling.

Although shown as part of system 200 in FIG. 2, in some embodiments,monitoring device 206 is not included in a device that includes pulsegenerator 202 and receiving circuit 204. In other words, monitoringdevice 206 is in a separate device. For example, pulse generator 202 andreceiving circuit 204 can be included on a first integrated circuit chip(e.g., microprocessor, controller, ASIC, etc.), while monitoring device206 is on a separate integrated circuit chip or device that is coupledto the first integrated circuit chip. In these embodiments, the numberof stages in the chain of pulse generators can be selected so that afrequency of the oscillating signal of the IDO is slow enough to enablemonitoring device 206 to receive the oscillating signal off-chip and/oraccurately measure the oscillating signal. For example, 80, 100, 200, oranother number of pulse generators can be coupled together to form anIDO with a desired oscillation frequency.

System 200 can be incorporated into many different types of electronicdevices. For example, system 200 can be part of a desktop computer, alaptop computer, a server, a media player, an appliance, a cellularphone, a piece of testing equipment, a network appliance, a personaldigital assistant (PDA), a hybrid device (i.e., a “smart phone”) oranother electronic device.

In some embodiments, some or all of system 200 is fabricated using oneor more integrated circuit chips. In these embodiments, the pulsed oroscillating signals generated within a given integrated circuit chip canbe passed off-chip to other integrated circuit chips for handling,forwarding, use, modification, or to be measured. For example, in someembodiments, pulse generator 202 and receiving circuit 204 arefabricated in one integrated circuit chip, while monitoring device 206is fabricated in another. In these embodiments, typical off-chipcommunication structures (i.e., traces in a circuit board, bonding pads,etc.) can be used for communicating between the integrated circuitchips.

Although we use specific components to describe system 200, inalternative embodiments different components may be present in system200. For example, system 200 may include one or more additionalreceiving circuits 204 for pulse generator 202. In addition, although weshow the input signals to pulse generator 202 as including a number ofsignals, in alternative embodiments, more or fewer signals can be usedas inputs for pulse generator 202.

In some embodiments, pulse generator 202 can be used without other pulsegenerators (e.g., pulse generators 201 and 203). For example, pulsegenerator 202 can be used in an IDO where one or more other stages areimplemented using different types of circuit elements, such as simple orcomplex logic gates. In addition, pulse generator 202 can be used inother types of circuits.

Inverting Difference Oscillator

FIG. 3A presents an inverting difference oscillator 300 in accordancewith the described embodiments. Inverting difference oscillator 300 is aconfigurable ring oscillator that enables the determination of the delayof a device under test (DUT) 302. As described in detail below, acircuit path in inverting difference oscillator 300 loops from DUT 302,through a configurable arrangement of inverter chains and bypass paths,and back to DUT 302. Generally, to determine the delay through DUT 302,a series of different mathematical expressions is generated using delaysmeasured through corresponding different configurations of the circuitpath loop. Then, using these expressions as inputs, mathematicaltechniques can be used to find the delay through the DUT.

Note that the device under test 302 in inverting difference oscillator300 is an inverting device. Unlike existing difference oscillators,which are only functional for non-inverting devices, the describedembodiments can test inverting devices. (However, the describedembodiments can also compute the delays for non-inverting devices, givena proper arrangement of the inverter chains in inverting differenceoscillator 300 using the technique described below.)

As shown in FIG. 3A, inverting difference oscillator 300 includes deviceunder test (DUT) 302, multiplexers (MUXes) 304, 308, and 312, inverterchains 306 and 310, and delay devices 314. DUT 302 is a device for whichthe delay (i.e., the propagation time for signals across the device) isto be measured. MUXes 304, 308, and 312 are selection circuits thatenable the configuration of different circuit paths through invertingdifference oscillator 300.

We generally refer to a given circuit element path and bypass path, andthe selection circuit to which the paths are coupled as a “stage” ininverting difference oscillator 300. For example, DUT 302, bypass path316, and MUX 304 form one stage, and inverter chain 306, bypass path318, and MUX 308 form another.

Inverter chains 306 and 310 are reference inverting stages that can beused to configure the number of inversions in the loop for invertingdifference oscillator 300 (note that we interchangeably refer toinverter chain 306 as “reference A” and to inverter chain 310 as“reference B”). Although we present an embodiment where each inverterchain 306 and 310 includes three inversions, in alternative embodimentsa different number of inversions can be used, including a differentnumber of inversions between the inverter chains. In addition, althoughonly two inverter chains are shown, alternative embodiments use adifferent number of inverter chains. Moreover, although simple invertersare shown for clarity, any inverting logic gate or functional block canbe used, such as an inverting logic gate/functional block, anon-inverting logic gate/functional block, a combination of invertingand non-inverting logic gates/functional blocks, etc.

Delay 314 includes a series of devices that are configured to slow thepropagation of signals around the circuit path loop in invertingdifference oscillator 300. In some embodiments, the propagation of asignal around the circuit path loop can be slowed using delay 314 toreduce the oscillation frequency of inverting difference oscillator 300.In some embodiments, the frequency of oscillation is selected inaccordance with the expected delay of DUT 302. If DUT 302 has a lowdelay (e.g., tens or hundreds of picoseconds), the frequency ofoscillation can be left high; otherwise, if DUT 302 has a high delay,the frequency of oscillation can be reduced. Generally, a higheroscillating frequency can enable these embodiments to more accuratelydetermine the delay for DUTs with lower delay times. Note thatadditional inverter chains coupled to MUXes (not shown) can also be usedto reduce the oscillating frequency of the ring oscillator.

As described generally above, when generating each of the expressionsthat is used to determine the delay of DUT 302, a corresponding patharound the circuit path loop is selected and MUXes 304, 308, and 312 areset to configure inverting difference oscillator 300 accordingly.Inverting difference oscillator 300 is then operated to generate anoscillating output signal and the frequency of the oscillation of theoutput signal is measured. From the measured frequency, a period ofoscillation can be determined, and from the determined period, a delayaround the circuit path loop can be computed. The computed delay canthen be placed in a mathematical expression that relates the delaythrough the inverting difference oscillator to the circuit elementspresent in the corresponding circuit path loop. The mathematicalexpressions for the configurations of the circuit path loop can then beused to determine the delay through DUT 302.

FIGS. 3B-3E present exemplary circuit path loop configurations in aninverting difference oscillator in accordance with the describedembodiments. The path around the circuit path loop in each configurationis shown using a heavy black line in FIGS. 3B-3E. Although invertingdifference oscillator 300 in FIG. 3B is the same as inverting differenceoscillator 300 shown in FIG. 3A, for clarity in describing thedetermination of the delay for DUT 302, groups of circuit elements arelabeled more simply using “DUT,” “reference A,” etc., which generallyrepresent the delay through the indicated circuit element paths.Unlabeled circuit elements may be described using the identificationnumbers shown in FIG. 3A.

As shown in FIG. 3B, MUX 304 is set to forward the output from DUT 302,and MUXes 308 and 312 are set to forward the outputs from circuit pathsreference A and reference B, respectively. Hence, the circuit path loopconfiguration shown in FIG. 3B causes a signal propagating aroundinverting difference oscillator 300 to propagate through DUT, referenceA, reference B, and other. The following expression can be used toexpress the delay in this configuration of the circuit path loop:DLY1=DUT+REF _(—) A+REF _(—) B+OTHER  (1)where the expression equates the delay of the path (i.e., DLY1) to thesum of the delays of the circuit elements that are present in the path(i.e., the DUT, etc.).

As shown in FIG. 3C, MUX 304 is set to bypass DUT, MUX 308 is set tobypass reference A (i.e., to forward the bypass path for the stage), andMUX 312 is set to forward the output from reference B. Hence, thecircuit path loop configuration shown in FIG. 3C causes a signalpropagating around inverting difference oscillator 300 to bypass DUT andreference A, but to propagate through reference B and other. Thefollowing expression can be used to express the delay in thisconfiguration of the circuit path loop:DLY2=0+0+REF _(—) B+OTHER  (2)

As shown in FIG. 3D, MUX 304 is set to forward the output from DUT, MUX308 is set to bypass reference A, and MUX 312 is set to bypass referenceB. Hence, the circuit path loop configuration shown in FIG. 3D causes asignal propagating around inverting difference oscillator 300 topropagate through DUT, bypass reference A and reference B, and propagatethrough other. The following expression can be used to express the delayin this configuration of the circuit path loop:DLY3=DUT+0+0+OTHER  (3)

As shown in FIG. 3E, MUX 304 is set to bypass DUT, MUX 308 is setforward the output from reference A, and MUX 312 is set to bypassreference B. Hence, the circuit path loop configuration shown in FIG. 3Ecauses a signal propagating around inverting difference oscillator 300to bypass DUT, propagate through reference A, bypass reference B, andpropagate through other. The following expression can be used to expressthe delay in this configuration of the circuit path loop:DLY4=0+REF _(—) A+0+OTHER  (4)

In the described embodiments, expressions 1-4 can then be used to solvefor the delay of the DUT as follows:DLY1−DLY2=(DUT+REF _(—) A+REF _(—) B+OTHER)−(0+0+REF _(—) B+OTHER),simplified:DLY1−DLY2=DUT+REF _(—) A  (5)DLY3−DLY4=(DUT+0+0+OTHER)−(0+REF _(—) A+0+OTHER),simplified:DLY3−DLY4=DUT−REF _(—) A  (6)Equation(5)+Equation(6)(DLY _(—)1−DLY _(—)2)+(DLY _(—)3−DLY _(—)4)=(DUT+REF _(—) A)+(DUT−REF_(—) A),simplified:(DLY _(—)1−DLY _(—)2)+(DLY _(—)3−DLY _(—)4)=2*DUT,and:DUT=((DLY _(—)1−DLY _(—)2)+(DLY _(—)3−DLY _(—)4))/2  (7)

In addition, in these embodiments, expressions 1-4 can be used in asimilar way to solve for the delay of REF_A as follows:Equation(5)−Equation(6)(DLY _(—)1−DLY _(—)2)−(DLY _(—)3−DLY _(—)4)=(DUT+REF _(—) A)−(DUT−REF_(—) A),simplified:(DLY _(—)1−DLY _(—)2)−(DLY _(—)3−DLY _(—)4)=2*REF _(—) A,and:REF _(—) A=((DLY _(—)1−DLY _(—)2)−(DLY _(—)3−DLY _(—)4))/2  (8)

Given expressions 7-8, with REF_A known, further DUT_(n) in a ring_(n)(i.e., in an inverting difference oscillator) with n number of devicesunder test can be measured similarly to DLY_(—)2:DUT _(n) =DLY1_(n) −DLY2_(n) −REF _(—) A  (9)

Some embodiments can include a microprocessor with general purposecircuits, or one or more ASICs or programmable-logic devices that can beconfigured to perform the computation. In some embodiments, the generalpurpose circuits can execute program code, firmware, or other code toconfigure the general purpose circuits to perform the computation.

As described above, the result of the computation can be conveyed to auser, an application, a test circuit, or another entity, or can bestored on a computer-readable storage medium.

Process for Using an Inverting Difference Oscillator

FIG. 4 presents a flowchart illustrating a process for computing a delayof a device under test using an IDO in accordance with the describedembodiments. The operations in the process shown in FIG. 4 are performedon an IDO with a similar structure to the IDO shown in FIG. 3A. Morespecifically, the operations in the process are performed on an IDO thatincludes a DUT stage and N reference stages with a selection device(e.g., a MUX) coupled between each stage.

The process starts when system 200 configures the selection devices inthe IDO to bypass selected stages to configure the reference circuitstages and the DUT as a ring oscillator (step 400). For example, usingthe circuit shown in FIGS. 3A-3E, the IDO can be configured as shown inone of FIGS. 3B-3E, or can be configured in another way. Note thatbypassing selected stages can involve bypassing none of the stages inthe IDO.

System 200 then operates the ring oscillator and measures the outputfrequency for the configuration of the ring oscillator (step 402). Forexample, in some embodiments, a monitoring device (e.g., monitoringdevice 206) can receive an oscillating signal from the IDO and count thenumber of rising or falling edges in the oscillating signal in a givenperiod of time to determine the frequency of the oscillating signal.Alternative embodiments can use different techniques for determining thefrequency of the oscillating signal (e.g., high or low peaks,zero-crossings, etc.).

System 200 then uses the frequency to compute the delay for theconfiguration of the ring oscillator (step 404). The period of the ringoscillator is twice the delay of the ring oscillator. Hence, determiningthe delay involves converting the frequency to a period and thendividing the period in half.

System 200 then determines if sufficient configurations of the IDO havebeen measured to determine the delay of the DUT (step 408). For example,assuming system 200 uses the technique described above with respect toequations 1-8 to compute the delay of the DUT, system 200 can determineif enough configurations have been measured to perform the computations.

If not, system 200 configures the selection devices to bypass selectedstages to configure the reference circuit stages and the DUT as a ringoscillator (step 406). When performing this operation, system 200 canselect a different configuration for the reference circuit stages thanwas previously used to compute a delay. For example, assuming a casewhere the IDO is similar to the IDO in FIGS. 3A-3E, and system 200 hasalready computed the delay for the configurations shown in FIGS. 3B and3D, system 200 can use the selection devices to configure the invertingdifference oscillator in an arrangement such as the configurations shownin FIG. 3C, FIG. 3E, or another configuration. System 200 then returnsto step 402 to operate the ring oscillator and measure the outputfrequency.

Otherwise, if sufficient configurations have been measured (step 408),system 200 uses the determined delays to compute a delay for the DUT(step 410). In some embodiments, determining the delay involvesperforming the operations described above with respect to equations 1-8.In alternative embodiments, different techniques can be used.

Pulse Generator

FIG. 5A presents a schematic view of a pulse generator 202 in accordancewith the described embodiments. Pulse generator 202 includes pulsegenerator circuit 500 and IDO enabling circuit 502. Generally, pulsegenerator circuit 500 generates pulses on output pg_out 216 when IDOenabling circuit 502 is disabled. In contrast, pulse generator 202 isconfigured as part of an IDO when IDO enabling circuit 502 is enabled.As described above with respect to FIG. 2, pulse generator 202 takesclock 208, pulse generator disable 210, functional/IDO mode control 212,and bypass control 214 as inputs.

As shown in FIG. 5A, the output of MUX 504 is coupled to the gateconnection of an n-type metal-oxide-semiconductor field-effect (NMOS)transistor in pulse generator circuit 500 and the top p-typemetal-oxide-semiconductor field-effect (PMOS) transistor in IDO enablingcircuit 502. Functional/IDO mode control 212 is coupled to the bottomPMOS transistor in IDO enabling circuit 502 and to the select input ofMUX 504.

When functional/IDO mode control 212 is asserted, the bottom PMOStransistor in IDO enabling circuit 502 is shut off, thereby preventingthe top PMOS transistor (for which the gate connection is coupled to theoutput of MUX 504) from affecting the value on the internal node ofpulse generator circuit 500. This leaves the NMOS transistor as the onlytransistor coupled to the output of MUX 504 that can affect the value onthe internal node of pulse generator circuit 500. In addition, whenfunctional/IDO mode control 212 is asserted, MUX 504 is configured toforward a signal from a feedback path for pulse generator 202 to theNMOS transistor in pulse generator circuit 500. In this configuration,pulse generator circuit 500 generates pulses on pg_out 216 in responseto rising edges on clock 208.

In contrast, when functional/IDO mode control 212 is deasserted, thebottom PMOS transistor in IDO enabling circuit 502 is enabled. When thisPMOS transistor is enabled, the combination of the top PMOS transistorin IDO enabling circuit 502 and the NMOS transistor in pulse generatorcircuit 500 form an inversion in the feedback path of pulse generatorcircuit 500. In addition, when functional/IDO mode control 212 isdeasserted, MUX 504 is configured to forward a signal received from aprevious pulse generator to the gate connections of the NMOS transistorin pulse generator circuit 500 and the top PMOS transistor in IDOenabling circuit 502, instead of forwarding pulse generator 202'sfeedback path. This inversion, in combination with the other inversionsin pulse generator circuit 500 (see e.g., encircled numbers 1-4 in FIG.4A), and any other inverting devices in an IDO chain to which pulsegenerator 202 is coupled, forms a ring oscillator within the IDO. Ringoscillators, as is well known in the art, are circuits with odd numbersof inverters that generate oscillating waveforms.

In some embodiments, when functional/IDO mode control 212 is asserted(i.e., when pulse generator is configured as part of the IDO), clock 108is held in a logical high state (i.e., held at VDD). In other words, inthese embodiments, clock 108 does not oscillate when pulse generator isconfigured as part of the IDO.

FIGS. 5B-5D present exemplary circuit paths within pulse generator 202that are taken according to whether functional/IDO mode control 212 andbypass control 214 are asserted and/or deasserted. More specifically,FIG. 5B shows an exemplary circuit path taken when functional/IDO modecontrol 212 is asserted (in this case, the asserted or deasserted stateof bypass control 214 does not matter), FIG. 5C shows an exemplarycircuit path taken when functional/IDO mode control 212 is deassertedand bypass control 214 is deasserted, and FIG. 5D shows an exemplarycircuit path taken when functional/IDO mode control 212 is deassertedand bypass control 214 is asserted.

In the first example, the functional/IDO mode control is asserted,disabling the PMOS transistor in IDO enabling circuit 502 and leavingonly the NMOS transistor that is coupled to the output of MUX 504 ableto affect the internal node in pulse generator circuit 500. As shown inFIG. 5B, for this configuration, the path through the circuit starts ata rising edge of clock 208, causes pg_out 216 to rise, and thenpropagates once around the internal feedback path, causing output pg_out216 to fall, thereby generating a pulse. However, when the fallen pg_out216 begins to propagate back into the feedback circuit, the propagationis stopped at the PMOS device in IDO enabling circuit 502 (as shown bythe “X” in FIG. 5B), because functional/IDO mode control 212 isdeasserted, thereby disabling the PMOS transistor stack in IDO enablingcircuit 502. Another pulse is therefore not generated until anotherrising edge occurs on clock 208.

In the second example, both functional/IDO mode control 212 and bypasscontrol 214 are deasserted. When functional/IDO mode control 212 isdeasserted, MUX 504 forwards a signal from a previous pulse generator inthe IDO chain into pulse generator circuit 500. In addition, the topPMOS transistor in IDO enabling circuit 502, in combination with theNMOS transistor in pulse generator circuit 500 coupled to the output ofMUX 504, form an inverter that is included as part of a ring oscillatorformed by pulse generator 202 and other pulse generators in an IDO. Asshown in FIG. 5C, in this configuration, the signal feeds from theprevious pulse generator in the IDO chain, through MUX 504 and into theinversion formed by the PMOS transistors in the IDO enabling circuit incombination with the NMOS transistor. The signal then feeds through theremaining inversions (inversions 1-4 in FIG. 5A) in pulse generatorcircuit 500 and to pg_out 216. From pg_out 216, the signal feeds to MUX506. Because bypass control 214 is deasserted, the signal is forwardedfrom MUX 506 to the next pulse generator in the IDO chain.

In the third example, functional/IDO mode control 212 is deasserted, butbypass control 214 is asserted. In this case, as shown in FIG. 5D, thesignal may propagate within pulse generator 202 as shown in FIG. 5C, butinstead of forwarding the signal from within pulse generator 202, bypasscontrol 214 configures MUX 506 to forward the signal from the previouspulse generator in the IDO chain directly to the next pulse generator inthe IDO chain. By configuring pulse generator 202 in this way, bypasscontrol 214 enables system 200 (or another controlling device) tocontrol the number of inverters in the IDO by adding or removing theinternal inversions in a given pulse generator to the IDO chain.

Configuring Pulse Generators as an Inverting Difference Oscillator

As described above with respect to FIG. 2, in some embodiments, pulsegenerators 201-203 can be configured as an IDO by deasserting a globalfunctional/IDO mode control 212. In some of these embodiments, the IDOformed from pulse generators 201-203 can be arranged similarly to theIDO shown in FIG. 3A. In this arrangement, the inverting DUT 302 andinverter chains 306 and 310 can be formed from the internal inversionsin pulse generators 201-203, and MUXes 304, 308, and 312 in the IDO canbe formed from MUXes 506 in pulse generators 201-203. (Note that in someembodiments one or more of the DUT, the inverter chains, and the MUXescan be formed from other circuit elements.)

For example, assuming that pulse generators 201-203 appear in the order201-203 from left to right in the IDO shown in FIG. 3A, the invertingDUT 302 is replaced by the internal inversions in pulse generator 201(of which there are five) and MUX 304 is replaced by MUX 506 in pulsegenerator 201. Inverter chain 306 and MUX 308 are replaced by theinternal inversions and MUX 506 in pulse generator 202, respectively,and inverter chain 310 and MUX 312 are replaced by the internalinversions and MUX 506 in pulse generator 203, respectively.

Although there are different numbers of inversions in pulse generators201-203 than are shown in DUT 302 or inverter chains 306 and 310 in FIG.3A, the function of the circuit does not change when replacing DUT 302or inverter chains 306 and 310 in FIG. 3A with the internal inversionsin pulse generators 201-203. This is true because the pulse generatorsare inverting (i.e., have an odd number of internal inversions), in thesame way as the single inversion in DUT 302 and the three inversions ininverter chains 306 and 310. Consequently, an IDO can function as a ringoscillator despite the use of pulse generators 201-203 as the DUT andinverter chains.

FIG. 6 presents a flowchart illustrating a process for configuring apulse generator (e.g., pulse generator 202) coupled to one or more otherpulse generators (e.g., pulse generators 201 and 203) as an IDO inaccordance with the described embodiments. Note that this process isbeing described for one pulse generator, but each pulse generator in theIDO chain can undergo a similar configuration process. For the purposesof illustration, we describe a circuit similar to the circuit shown inFIG. 2, where pulse generators 201-203 are coupled in series, which canbe functionally equivalent to the figures shown in FIG. 3A-3E. Althoughwe use a particular arrangement of circuit elements to present thefunctions of the described embodiments, other arrangements of pulsegenerators, or other circuit elements (e.g., logic gates, etc.) may beused.

The process starts with system 200 operating pulse generator 202 in apulse generation mode (step 600). In the pulse generation mode, thefunctional/IDO mode control 212 signal is asserted, preventing the topPMOS transistor in IDO enabling circuit 502 (in combination with theNMOS transistor coupled to the output of MUX 504) from forming a fullinversion on the output of MUX 504. In addition, MUX 504 is set toforward a feedback path into pulse generator circuit 500. Hence, pulsegenerator 202 outputs pulses on pg_out 216 (using the circuit path shownin FIG. 5B).

System 200 then determines whether pulse generator 202 is to beconfigured as part of an IDO (step 602). More specifically, system 200determines whether series-coupled pulse generators 201-203 are each tobe configured as a portion of a configurable ring oscillator in an IDOchain. If not, system 200 continues to operate pulse generator 202 inthe pulse generation mode (step 600).

Otherwise, system 200 deasserts the functional/IDO mode control 212signal to select the output of a previous pulse generator (i.e., pulsegenerator 201) as an input for the pulse generator and to configure thepulse generator as part of an IDO chain (step 604). More specifically,deasserting functional/IDO mode control 212 causes MUX 504 to forwardthe output of pulse generator 201 into pulse generator circuit 500. Inaddition, deasserting functional/IDO mode control 212 unblocks the PMOStransistor coupled to the output of MUX 504 to configure the NMOStransistor and PMOS transistor coupled to the output of MUX 504 as aninverter, causing pulse generator 202 to use the circuit path shown inFIG. 5C.

System 200 then determines if pulse generator 202 is to be bypassed(step 606). For example, if the IDO is to be configured without theinversions in pulse generator 202, system 200 can determine that pulsegenerator 202 is to be bypassed. If pulse generator 202 is to bebypassed, system 200 asserts the bypass signal to cause pulse generator202 to be bypassed in the IDO chain (step 608). Recall that bypassingpulse generator 202 causes the oscillating signal to be passed frompulse generator 201 directly through pulse generator 202, and to pulsegenerator 203, as is shown by the circuit path in FIG. 5D. Hence, pulsegenerator 202 has no effect on the oscillating state of the bypassedsignal (i.e., does not cause a delay in the bypassed signal).

System 200 then operates the IDO (step 610). Note that this can involveoperating the IDO with or without pulse generator 202, depending on thestate of the bypass control 214 signal for pulse generator 202.

The foregoing descriptions of embodiments have been presented only forpurposes of illustration and description. They are not intended to beexhaustive or to limit the embodiments to the forms disclosed.Accordingly, many modifications and variations will be apparent topractitioners skilled in the art. Additionally, the above disclosure isnot intended to limit the embodiments. The scope of the embodiments isdefined by the appended claims.

What is claimed is:
 1. A configurable pulse generator circuit,comprising: the pulse generator circuit; an inverting differenceoscillator (IDO) enabling circuit coupled to the pulse generatorcircuit; and a disable signal coupled to the IDO enabling circuit;wherein when the disable signal is asserted, the IDO enabling circuit isdisabled and the pulse generator circuit is configured as a pulsegenerator; and wherein when the disable signal is deasserted, the IDOenabling circuit is enabled and the pulse generator circuit isconfigured as part of an IDO.
 2. The pulse generator circuit of claim 1,further comprising: a selection circuit, wherein one input of theselection circuit is coupled to an output of a previous pulse generatorcircuit and another input of the selection circuit is coupled to anoutput of the pulse generator circuit, and wherein a control input ofthe selection circuit is coupled to the disable signal; wherein when thedisable signal is deasserted, the selection circuit is configured toforward the output from the previous pulse generator circuit to thepulse generator circuit; and wherein when the disable signal isasserted, the selection circuit is configured to forward the output ofthe pulse generator circuit as a feedback to the pulse generatorcircuit.
 3. The pulse generator circuit of claim 2, comprising: ann-type metal-oxide-semiconductor field-effect (NMOS) transistor in thepulse generator circuit coupled between an internal node in the pulsegenerator circuit and VSS, wherein a gate connection for the NMOStransistor is coupled to an output from the selection circuit; and twop-type metal-oxide-semiconductor field-effect (PMOS) transistors in theIDO enabling circuit coupled in series between the internal node in thepulse generator circuit and VDD, wherein a gate connection for the firstof the PMOS transistors is coupled to the disable signal, and wherein agate connection for the second of the PMOS transistors is coupled to theoutput of the selection circuit.
 4. The pulse generator circuit of claim3, comprising: a second selection circuit, wherein one input of thesecond selection circuit is coupled to the output of the previous pulsegenerator circuit, and another input of the selection circuit is coupledto the output of the pulse generator circuit, and wherein a controlinput of the selection circuit is coupled to a bypass signal; whereinwhen the bypass signal is assserted, the second selection circuit isconfigured to forward the output of the previous pulse generator circuitto a subsequent pulse generator circuit without the signal propagatingthrough a set of inverting circuit elements in the pulse generatorcircuit; and wherein when the bypass signal is deasserted, the secondselection circuit is configured to forward the output of the pulsegenerator circuit to the subsequent pulse generator circuit.
 5. Thepulse generator circuit of claim 1, further comprising: a clock signalcoupled to the pulse generator circuit, wherein when configured as apulse generator, the pulse generator circuit is configured to outputpulses in response to each rising edge of the clock signal, and whereinwhen configured as part of the IDO the clock signal is configured toremain at a steady signal level.
 6. The pulse generator circuit of claim1, further comprising: a second disable signal coupled to the pulsegenerator circuit, wherein the pulse generator circuit is configured sothat the pulse generator circuit is disabled when the second disablesignal is asserted, and wherein when the pulse generator circuit isdisabled, the pulse generator circuit outputs a non-varying signal at apredetermined voltage level.
 7. The pulse generator circuit of claim 1,further comprising: a receiving circuit coupled to the output of thepulse generator circuit, wherein the receiving circuit is configured touse the pulses output from the pulse generator circuit as a control,timing, or data input.
 8. The pulse generator circuit of claim 1,further comprising a monitoring device coupled to the output of thepulse generator circuit, wherein the monitoring device is configured tomeasure a waveform output by the pulse generator circuit when the pulsegenerator circuit is configured as part of the IDO.
 9. A method forconfiguring a pulse generator circuit, comprising: operating the pulsegenerator circuit in a pulse generation mode; and configuring the pulsegenerator circuit to operate in an inverting difference oscillator (IDO)mode by deasserting a disable signal coupled to the pulse generatorcircuit to select an output of a previous pulse generator circuit as aninput for the pulse generator circuit, wherein the IDO mode is differentfrom the pulse generation mode, and wherein configuring the pulsegenerator circuit to operate in the IDO mode includes configuring PMOStransistors in an IDO circuit coupled to the pulse generator circuit sothat a full inverter is present on a circuit path in the pulse generatorcircuit to configure the pulse generator circuit as part of a ringoscillator in an IDO.
 10. The method of claim 9, wherein the methodfurther comprises: determining that the pulse generator circuit is to bebypassed in the IDO; and asserting a bypass signal to bypass a signal inthe IDO from the previous pulse generator circuit to a subsequent pulsegenerator circuit without propagating the signal through the circuitpath in the pulse generator circuit.
 11. The method of claim 9, whereinthe method further comprises: operating the pulse generator circuit aspart of the IDO; and configuring the pulse generator circuit as a pulsegenerator by asserting the disable signal coupled to the pulse generatorcircuit to select the output of the pulse generator circuit as afeedback input for the pulse generator circuit and to configure thepulse generator circuit in a pulse generator mode; wherein configuringthe pulse generator circuit in the pulse generator mode includesconfiguring a PMOS transistor in the IDO circuit to remove the fullinverter from the circuit path in the pulse generator circuit.
 12. Themethod of claim 9, further comprising: configuring the pulse generatorcircuit as a pulse generator by asserting the disable signal coupled tothe pulse generator circuit to select the output of the pulse generatorcircuit as a feedback input for the pulse generator circuit.
 13. Themethod of claim 12, wherein the deasserting configures the pulsegenerator circuit to operate in the IDO mode.
 14. The method of claim 9,further comprising: configuring the pulse generator circuit as a pulsegenerator by asserting the disable signal coupled to the pulse generatorcircuit to select the output of the pulse generator circuit as afeedback input for the pulse generator circuit and to configure thepulse generator circuit in a pulse generator mode.